RU2236650C1 - Contact water heater - Google Patents

Abstract

FIELD: heat power engineering.

SUBSTANCE: invention relates to water heaters with direct contact between smoke gases produced at combustion of gaseous fuel and water to be heated. According to invention, in contact water heater including housing with contact chamber, heated water collector in lower part and fire tube made of two shells to housing and connected at end faces by ring inserts, lower end of fire tube is provided with contraction, and water sprayers are installed directly under contraction, and screw partition is placed between shells, or flat vertical plates are mounted, being connected with upper and lower ring inserts to form zigzag channel to pass water. Invention is aimed at simplifying design of contact water heater.

EFFECT: reduced overall dimensions of heater and its metal usage, increased intensity and improved reliability in operation, facilitated manufacturing.

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Description

The invention relates to the field of power engineering and, in particular, to designs of water heaters with direct contact of flue gases obtained by burning gaseous fuel and heated water.

Known contact water heater containing a housing, in the lower part of which there is a firebox with refractory lining, where the process of burning natural gas, and hence the formation of flue gases. In the contact chamber there is an active interaction of flue gases and water, during which the water is heated up to the temperature of the wet thermometer when the corresponding balance ratios are fulfilled. The furnace is built into the lower part of the case in such a way that in the annular space between the wall of the case and the furnace, which is a collection of heated water, there is an additional increase in its temperature, which, as a result of the process, exceeds the temperature of the wet thermometer. The contact chamber is separated from the furnace by a super-heating disk, which prevents water from entering the furnace and directs it into the annular space (see, for example, Sosnin Yu.P. Contact water heaters. M: Stroyizdat, 1974, p.6-8). The main disadvantages of such a contact water heater are the complexity of the design, the difficult operating conditions of the furnace and the increased dimensions of the apparatus.

Known contact water heater, in which due to the formation of the lower part of the casing of metal shells, the conditions for heating water are improved (see, for example, Sosnin Yu.P. Contact water heaters. M: Stroyizdat, 1974, p. 9). The main disadvantages of such a contact water heater are the unreliability of the operation of the furnace due to the high temperature of the gases, the practical impossibility of preventing the undesirable effect of the torch on the walls of the furnace and in increased metal consumption. The dimensions of the device are also not satisfactory.

A contact water heater is known, which includes the same main components: a housing with a contact chamber and a water collector in its lower part, a heating disk and a furnace made of metal shells, but additionally having a water spray located directly in the furnace, which makes it possible to reduce the height of the contact chamber (see, for example, RF patent RU 2134845 C1, filed April 17, 1998, published August 20, 1999, bull. No. 23). The main disadvantages of this type of water heater remain.

Known contact water heater with a remote water-cooled furnace, which undergoes the initial cooling of flue gases (see, for example, Druskin LI Effective use of natural gas in industrial plants. Reference manual. M: Energoatomizdat, 1992, p. 115-117) . The disadvantages of such an apparatus also lie in the complexity of the design and manufacturing technology, insufficient efficiency and increased dimensions.

The contact water heater closest to the present technical solution includes a heat pipe (firebox) vertically located in the center of the body, the heat pipe being surrounded by a water jacket formed by an additional ring shell (see, USSR Author's Certificate No. 787812, published on 15.12.80, Bulletin No. 46). The installation of a heat pipe directly in the apparatus allows you to implement a fairly compact design. The dimensions of the device (especially its height) are unsatisfactory. A contact water heater of this type is notable for the insufficient intensity of the heat and mass transfer processes and the practical inevitability of boiling water in a water jacket.

The objective of the present invention is to intensify the heat and mass transfer processes taking place in the contact water heater.

The technical result is to reduce the size of the apparatus and its metal consumption, increase the reliability of its operation, eliminating the possibility of boiling water in a water jacket.

The specified technical result is achieved due to the fact that in the contact water heater, which includes a housing with a contact chamber, a heated water collector in the lower part and a heat pipe made of two ring inserts connected to the ends of the shells coaxial to the shell, the lower end of the heat pipe is equipped with a confuser directly under water dispensers are placed there, and a helical partition is installed between the shells or flat vertical plates are placed connected to the upper and lower annular inserts with the formation of zig an oblique channel for the passage of water.

The essence of the present invention is as follows.

The high-temperature gas produced in the furnace of a water heater is capable of actively evaporating the liquid, and even more so if the latter is brought into contact with the gas in the form of small droplets. The contact of water and hot gases in the contact chamber on the lower layers of the nozzle usually results in an increase in water temperature to a temperature exceeding the dew point of the flue gas. In this case, however, the water temperature remains below the temperature of the wet thermometer, which is the limit for heating water with gases of a given initial moisture content and temperature. When water evaporates into a gas, its moisture content increases to a state characterized by a secondary dew point, after which only vapor condensation from the gas occurs. A gas state close to the secondary dew point can be achieved by supplying the corresponding amount of water undergoing complete evaporation into the hot gas (it is obvious that this amount of water is much lower than that heated in the apparatus). The expediency of the process of complete evaporation of water to the contact chamber, and more precisely in the area under the flame tube, is obvious. In this case, the required contact surface in the contact chamber is determined only by the condensation process, and therefore, represents a value much smaller than in the case when a certain nozzle surface is required for the evaporation process. A decrease in the height of the nozzle (in the case of using a nozzle contact chamber) characterizes an increase in the intensity of the contact water heater as a whole. It is for carrying out active contact of water in finely dispersed form and flue gases that water sprayers installed under the flame tube are used.

The evaporation of water in front of the contact chamber takes place more intensively with an increase in the rate of gas outflow from the flame tube. Reducing the actual diameter of the flame tube is unacceptable, because Thermal voltage goes beyond permissible limits. It is advisable to increase the speed of flue gases by installing a confuser at the exit of the flame tube.

Currently, various types of contact chambers are widely used: nozzle, cascade, and mainly packed ones (see, for example, Sosnin Yu.P. Contact water heaters. M: Stroyizdat, 1974, p. 55-77; Druskin LI Effective the use of natural gas in industrial plants. Reference manual. M.: Energoatomizdat, 1992, p.113-114). In the area of the contact chamber proper, water can be heated when the balance ratios are fulfilled, as mentioned above, only to the temperature of the wet thermometer. Since it is advisable to obtain and use water with a higher final temperature, the latter can be achieved by heating the water in the jacket of the flame tube. When considering the thermal and material balance of the water heater, it was found that in the water jacket the temperature of the wall from the side of the flue gases is such that water boils inevitably on the surface of the flame tube. It is possible to lower the wall temperature only by increasing the water velocity in the zone of the water jacket (annular channel). The speed of water in the annular channel can be increased, for example, by placing a special screw-shaped partition in it. The partitions can also be made in the form of vertically mounted flat plates connected to the upper and lower annular partition of the annular channel so that a zigzag channel is formed between the vertical partitions for water passage.

The design of the contact water heater of the present invention is shown in the drawing.

The contact water heater comprises a housing 1 with a cover 2, a contact chamber 3 and a collector of heated water 4. A heat pipe 5 is placed in the center of the housing 1. The heat pipe 5 is made of two coaxial shells 6 and 7, connected at the ends by ring partitions 8 and 9.

The flame tube is equipped with fittings 10 and 11, respectively, for supplying and discharging water. In this case, two vertical partitions 12 and 13 are installed between the shells 6 and 7, and both partitions have a length shorter than the length of the shells and are connected to the upper annular partition 8. In this case, a zigzag channel is formed between the shells 6 and 7 for water passage with descending 14 and ascending 15 branch. In the upper part, the flame tube 5 is connected to the cover 2 of the housing 1. The lower end of the flame tube 5 is connected to the housing 1 by means of a support grid 16 on which the nozzle 17 is placed (for example, a Raschig ring.). A distributor 18 is installed on the return water line inside the housing 1. The heated water collector 4 is equipped with a nozzle 19 connected to the suction line of the pump 20. The discharge line of the pump 20 is connected to the nozzle for supplying water 10. The upper end of the flame tube 5 is equipped with a gas burner device 21 (with the corresponding Elements: pressure regulator, natural gas flow meter, etc.). The collection 4 has appropriate devices for maintaining and regulating the water level (not shown). With a large consumption of hot water by the consumer with its withdrawal from circulation, the nozzle 17 can be made of two tiers with irrigation of the upper tier with cold fresh water. The heat pipe 5 in the lower part is equipped with a confuser 22. A water spray 23 is mounted directly under the confuser 22, which is connected to the discharge line of the pump 20. Thus, in this embodiment, the spray 23 and nozzle 10 are arranged parallel to the water.

Contact water heater, corresponding to the drawing and the present invention, operates as follows.

Natural gas is supplied to a gas burner device 21 (in this case, a gas burner device with forced air supply is used). Natural gas is burned at a certain excess air ratio. Flue gases enter the flame tube 5 (similar to the work of the well-known fire tube boilers). From the flame tube 5, hot flue gases exit to the lower part of the housing 1 through the confuser 22, contact at an increased speed with water droplets formed during operation of the atomizer 23, the water into which comes from the pressure line of the pump 20, and with the water surface in the heated water collector 4 giving warmth to the water and saturating it with vapors. In fact, the primary contact of the flue gases and water passes under the confuser 22, the secondary - when the flue gases come into contact with the surface of the water in the collector 4. Next, the flue gases unfold and pass through the support grid 16 and enter the nozzle zone 17 of the contact chamber 3. The nozzle 17 is irrigated recycled water with the addition of fresh water to make up for losses with fumes carried by the flue gases into the atmosphere. Uniform distribution of water over the nozzle is carried out using a distributor 18. On nozzle 17, there is subsequent active contact between water and flue gases, during which the water is heated and the flue gas is saturated with water vapor, and then, continuing to cool, goes over the secondary dew point. After this, the process of condensation of water vapor passes with the transfer of heat to the heated water. The water flowing into the collection 4 can be extremely heated to the temperature of the wet thermometer, and the gases at the outlet of the nozzle are extremely cooled to the temperature of the water entering the nozzle. The heat pipe 5 itself is made of two coaxial shells 6 and 7. The shells are connected in the area of the upper and lower end by means of the annular partitions 8 and 9. The outer shell 6 is connected to the cover 2 of the housing 1 and to the housing 1 using the support grid 16. In the gap between the shells 6 and 7, two flat vertical partitions 12 and 13 are connected in this embodiment, connected to the annular partition 8. In the upper part of the flame tube 5 there are nozzles 10 and 11, respectively, for supplying and discharging water. Heated water from the collector 4, equipped with a nozzle 19 for water outlet, enters the suction line of the pump 20, the pressure line of which is connected to the nozzle 10 and to the nozzle 23. The water after the nozzle 10 passes further into the zigzag channel, moving down the descending branch 14, and further up the ascending branch 15. Thus, in this case, the water speed is doubled compared with the absence of vertical partitions 12 and 13. An increase in water speed allows for intensive additional heating of water without boiling it on heat exchange surface of the shell 7. This in turn helps to increase the reliability of the apparatus by reducing the risk of overgrowth of the zigzag channel with hardness salts. Through the fitting 11, additionally heated water with a temperature exceeding the temperature of the wet thermometer, if necessary, enters the consumer. From the consumer, chilled water flows back to the distributor 18 and then to the nozzle 17.

In the contact water heater of the present invention:

it is possible to increase the speed of the water washing the flame tube, which prevents the mode of boiling water and the formation of scale,

several stages of contact of water and flue gases are provided, the contact of flue gases with water droplets from a spray helps to reduce the height of the apparatus,

the intensity of contact with water droplets from the atomizer is increased due to an increase in gas velocity, due to equipping the flame tube with a confuser.

Thus, due to the distinguishing features, the operation of the device has been significantly intensified and its reliability has been increased.

Claims (1)

A contact water heater, comprising a housing with a contact chamber, a heated water collector in the lower part and a flame tube made of two annular inserts connected at the ends by coaxial shell shells, characterized in that the lower end of the flame tube is equipped with a confuser, water sprayers are placed directly underneath, and a helical partition is installed between the shells or flat vertical plates are placed, connected to the upper and lower annular inserts with the formation of a zigzag channel for water passage s.